A revised method for generation of unitary postsynaptic potentials for quantal analysis in the hippocampus

For quantal analysis of excitatory postsynaptic potentials (EPSPs) in hippocampal CA3 neurons, a method was devised to evoke trains of unitary EPSPs at intended intervals and to control the number of unitary EPSPs composing each train at will. The amplitudes of the first EPSPs in EPSP trains evoked with this method were measured. From the mean and variance of the EPSP amplitudes, the mean number of quanta (m) released by a single impulse and the mean amplitude of EPSPs induced by individual quanta (q) were estimated in a standard solution and in a high calcium solution.     

Enhancement of postsynaptic responsiveness during long-term potentiation of mossy fiber synapses in guinea pig hippocampus.

The primary site responsible for the long-lasting enhancement of synaptic transmission during long-term potentiation (LTP) was examined by quantal analysis of excitatory postsynaptic potentials in thin sections of the guinea pig hippocampus. With induction of LTP in mossy fiber synapses, estimated values of quantal amplitude (q) and Pascal parameters p and r were increased significantly. No increases in quantal content (m) were detected. The magnitude of increases in q was almost equal to that of LTP. These results indicate that LTP in mossy fiber synapses results from increases in responsiveness of postsynaptic neurons.     

Analysis of potentiation in the cerebral ganglion of Aplysia.

Quantal analysis was used to characterize synaptic transmission between A and B neurons in the cerebral ganglion of Aplysia in control and during slow developing potentiation, a form of synaptic plasticity exhibited by these synapses. Control values of mean quantal content (m) and quantal size (q) estimated by the method of coefficient of variation (CV) were m approximately 6, q approximately 56 microV in the solution with Ca2+/Mg2+ = 5/200 and m approximately 18, q approximately 41 microV in the solution with Ca2+/Mg2+ = 55/150. There was a good correlation between an increase in the amplitude of excitatory synaptic potential and an increase in calculated quantal content (m(cv)) during potentiation. A decrease of Ca2+/Mg2+ ratio in the bath solution allowed observation of transmission failures and in some cases regular peaks on excitatory postsynaptic potential amplitude histograms. The latter provided more direct estimate of the quantal size. Induction of the potentiation in this solution, however, became difficult. In cases of successful potentiation induction, probability of failures was less than in control; distances between histogram peaks, reflecting quantal size remained the same. The results obtained in this study support a hypothesis that potentiation of the synaptic transmission between A and B neurons of Aplysia is primarily due to an increase of transmitter release.     

Mechanism for increased hippocampal synaptic strength following differential experience

Exposure to novel environments or behavioral training is associated with increased strength at hippocampal synapses. The present study employed quantal analysis techniques to examine the mechanism supporting changes in synaptic transmission that occur following differential behavioral experience. Measures of CA1 synaptic strength were obtained from hippocampal slices of rats exposed to novel environments or maintained in individual cages. The input/output (I/O) curve of extracellularly recorded population excitatory postsynaptic potentials (EPSPs) increased for animals exposed to enrichment. The amplitude of the synaptic response of the field potential was related to the fiber potential amplitude and the paired-pulse ratio, however, these measures were not altered by differential experience. Estimates of biophysical parameters of transmission were determined for intracellularly recorded unitary responses of CA1 pyramidal cells. Enrichment was associated with an increase in the mean unitary synaptic response, an increase in quantal size, and a trend for decreased input resistance and reduction in the stimulation threshold to elicit a unitary response. Paired-pulse facilitation, the percent of response failures, coefficient of variance, and estimates of quantal content were not altered by experience but correlated well with the mean unitary response amplitude. The results suggest that baseline synaptic strength is determined, to a large extent, by presynaptic release mechanisms. However, increased synaptic transmission following environmental enrichment is likely due to an increase in the number or efficacy of receptors at some synapses and the emergence of functional synaptic contacts between previously unconnected CA3 and CA1 cells.     

Primary afferent-evoked synaptic responses and slow potential generation in rat substantia gelatinosa neurons in vitro

1. Primary afferent fiber-evoked synaptic responses and the mechanisms of spike and slow potential generation have been examined in adult rat substantia gelatinosa (SG) neurons in an in vitro transverse spinal cord slice preparation in which an attached dorsal root is retained. Intracellular recordings were made from SG neurons identified by morphological and electrophysiological criteria. Afferent fiber-evoked fast excitatory postsynaptic potentials (fast EPSPs) and slow EPSPs have been analyzed. 2. SG neurons had mean resting membrane potentials of -67.1 +/- 0.5 mV (mean +/- SE), mean input resistance of 257 +/- 17.7 (SE) M omega, and a mean time constant of 21.3 +/- 1.9 ms and exhibited spontaneous EPSPs. 3. Single low-intensity stimuli applied to the dorsal root using a suction electrode produced, in 70% of SG neurons, short-latency, presumed monosynaptic fast EPSPs which had a half decay time of 10-30 ms and an amplitude of 8-28 mV. The conduction velocity of afferent fibers evoking fast EPSPs was 2-7 m/s, corresponding to that of thinly myelinated A-delta-fibers. Dorsal root stimulation at higher intensities evoked, in 10% of SG neurons, long-latency and apparently monosynaptic EPSPs which had a time course and amplitude similar to that evoked by low-intensity stimulation. The conduction velocity of fibers evoking long-latency EPSPs was 0.4-2 m/s, suggesting that they constitute predominantly C-fibers. A-delta- and C-fiber-mediated fast EPSPs were detected in 20% of SG neurons examined. 4. Low-intensity stimuli produced slow EPSPs in 20% of SG neurons. Slow EPSPs were 3-15 mV in amplitude and of up to 2 min in duration. A-delta-fibers appeared to be responsible for the generation of slow EPSPs. Slow EPSPs were associated with an increase in membrane resistance and were decreased in amplitude with membrane hyperpolarization. 5. Action potentials in SG neurons had a mean amplitude of 76.3 +/- 1.1 mV and a mean duration of 1.0 +/- 0.07 ms. Na+ ions represent the main charge carrier during the rising phase of the action potential and Ca2+ ions contribute to the shoulder on the falling phase. 6. In 20% of SG neurons, subthreshold depolarizing pulses were followed by long-lasting slow-inactivating depolarizing potentials which were able to initiate spikes. The slow depolarizing potentials were blocked by TTX and enhanced by application of TEA and Ba2+, suggesting that Na+ and K+ are involved in this slow-inactivating potential.(ABSTRACT TRUNCATED AT 400 WORDS)     

A correlative physiological and morphological analysis of monosynaptically connected propriospinal axon-motoneuron pairs in the lumbar spinal cord of frogs

Intracellular stimulation of single propriospinal axons evoked excitatory postsynaptic potentials (EPSPs) in lumbar motoneurons. Mean EPSP amplitudes differed by two orders of magnitude when measured in different connections. After analyzing the distribution of mean amplitudes of 47 single-fiber EPSPs, two populations of responses could be defined: (1) those with mean amplitudes between 0.1 and 1.2 mV (mean+/-S.D.: 0.48+/-0.30 mV, 34 pairs), which is in the range of values typical for single-fiber EPSPs evoked by stimulation of supraspinal fibers and primary muscle afferents, (2) those with mean amplitudes between 1.6 and 8 mV (4.2+/-2.0 mV, 13 pairs). Both populations of responses had similarly short latencies and rise times and responded similarly to paired-pulse stimulation, consistent with monosynaptic transmission. However, the high-efficacy connections had significantly smaller coefficients of variation of EPSPs, as well as increased quantal content and quantal size. Tetanic stimulation gradually depressed the amplitude of large EPSPs by 81-86%, but did not affect small EPSPs. Recovery of large EPSPs was exponential with a time constant of 3-5.6 min. During post-tetanic depression the amplitude ratio between the test and conditioned EPSPs evoked by paired-pulse stimulation was not changed but the coefficient of variation was increased, suggesting that the depression was due to depletion of synaptic vesicles available for release.Intracellular labeling of seven electrophysiologically studied propriospinal axon-motoneuron pairs revealed that the number of axon varicosities establishing close appositions with dendrites of the labeled motoneuron was higher for connections where large-amplitude EPSPs were recorded. These varicosities were more often located on proximal dendrites of motoneurons than those of low-efficacy connections. In addition, the number of boutons in highly effective connections was several times lower than the maximal number of available quanta estimated from physiological data, implying that the large EPSPs may be generated by multivesicular release from presynaptic boutons.We conclude that the efficacy and related mode of use-dependent modulation of propriospinal connections is determined by a number of factors, including the number and position of synaptic contacts and the number of active zones or vesicles available for release.     

Simultaneous recording of presynaptic spikes and excitatory postsynaptic potentials from monosynaptically connected hippocampal neurons

A technique has been devised to activate single granule cells in the hippocampus, and to record simultaneously spikes from the particular granule cell and excitatory postsynaptic potentials from a monosynaptically connected CA3 neuron. The unitary excitatory postsynaptic potentials (EPSPs) sustained for long observation periods, and increased in size with increases in stimulus frequency and in external Ca2+ concentration. This technique may be useful for quantal analysis of transmission through the synapse between mossy fibers and CA3 neurons.     

Role of EPSPs in initiation of spontaneous synchronized burst firing in rat hippocampal neurons bathed in high potassium

1. Spontaneous discharges that resemble interictal spikes arise in area CA3 b/c of rat hippocampal slices bathed in 8.5 mM [K+]o. Excitatory postsynaptic potentials (EPSPs) also appear at irregular intervals in these cells. The role of local synaptic excitation in burst initiation was examined with intracellular and extracellular recordings from CA3 pyramidal neurons. 2. Most (70%) EPSPs were small (less than 2 mV in amplitude), suggesting that they were the product of quantal release or were evoked by a single presynaptic action potential in another cell. It is unlikely that most EPSPs were evoked by a presynaptic burst of action potentials. Indeed, intrinsic burst firing was not prominent in CA3 b/c pyramidal cells perfused in 8.5 mM [K+]o. 3. The likelihood of occurrence and the amplitude of EPSPs were higher in the 50-ms interval just before the onset of each burst than during a similar interval 250 ms before the burst. This likely reflects increased firing probability of CA3 neurons as they emerge from the afterhyperpolarization (AHP) and conductance shunt associated with the previous burst. 4. Perfusion with 2 microM 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), a potent quisqualate receptor antagonist, decreased the frequency of EPSPs in CA3 b/c neurons from 3.6 +/- 0.9 to 0.9 +/- 0.3 (SE) Hz. Likewise, CNQX reversibly reduced the amplitude of evoked EPSPs in CA3 b/c cells. 5. Spontaneous burst firing in 8.5 mM [K+]o was abolished in 11 of 31 slices perfused with 2 microM CNQX.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibitor of glutamate transport alters synaptic transmission at sensorimotor synapses in Aplysia

Aplysia sensory neurons possess high-affinity glutamate uptake activity that is regulated by serotonin. To gain insight into the physiological role of glutamate uptake in sensory neurons, we examined whether blockade of glutamate transport altered synaptic transmission. We also examined whether glutamate transport affected homosynaptic depression and posttetanic potentiation (PTP). In the presence of DL-threo-beta-hydroxyaspartic acid (THA), previously shown to block glutamate uptake in Aplysia, the duration of unitary excitatory postsynaptic potentials (EPSPs) was significantly increased and their amplitude was significantly reduced. Similar effects were observed in the properties of summated EPSPs. However, no effect on the induction of homosynaptic depression or PTP was observed. Although it is unclear whether THA exerted its effect by modulating neuronal and/or glial mechanisms, at least one target of THA was neuronal, as the duration of unitary EPSPs measured in cultured sensorimotor synapses was also increased in the presence of THA. These results support the hypotheses that glutamate is the transmitter released by the sensory neurons and that glutamate transport plays an important role in regulating features of synaptic transmission in Aplysia.     

Postsynaptic glutamate receptors and integrative properties of fast-spiking interneurons in the rat neocortex.

The glutamate-mediated synaptic responses of neocortical pyramidal cell to fast-spiking interneuron (pyramidal-FS) connections were studied by performing paired recordings at 30-33 degrees C in acute slices of 14- to 35-day-old rats (n = 39). Postsynaptic fast-spiking (FS) cells were recorded in whole cell configuration with a patch pipette, and presynaptic pyramidal cells were impaled with sharp intracellular electrodes. At a holding potential of -72 mV (near the resting membrane potential), unitary excitatory postsynaptic potentials (EPSPs) had a mean amplitude of 2.1 +/- 1.3 mV and a mean width at half-amplitude of 10.5 +/- 3.7 ms (n = 18). Bath application of the N-methyl-D-aspartate (NMDA) receptor antagonist D(-)2-amino-5-phosphonovaleric acid (D-AP5) had minor effects on both the amplitude and the duration of unitary EPSPs, whereas the alpha-amino-3-hydroxy-5-methyl-4-isoxazole-propionate (AMPA)/kainate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) almost completely blocked the synaptic responses. In voltage-clamp mode, the selective antagonist of AMPA receptors 1-(4-aminophenyl)-3-methylcarbamyl-4-methyl-7,8-methylenedioxy-3, 4-dihydro-5H-2,3-benzodiazepine (GYKI 53655; 40-66 microM) blocked 96 +/- 1.9% of D-AP5-insensitive unitary excitatory postsynaptic currents (EPSCs), confirming the predominance of AMPA receptors, as opposed to kainate receptors, at pyramidal-FS connections (n = 3). Unitary EPSCs mediated by AMPA receptors had fast rise times (0.29 +/- 0.04 ms) and amplitude-weighted decay time constants (2 +/- 0.8 ms; n = 16). In the presence of intracellular spermine, these currents showed the characteristic rectifying current-voltage (I-V) curve of calcium-permeable AMPA receptors. A slower component mediated by NMDA receptors was observed when unitary synaptic currents were recorded at a membrane potential more positive than -50 mV. In response to short trains of moderately high-frequency (67 Hz) presynaptic action potentials, we observed only a limited temporal summation of unitary EPSPs, probably because of the rapid kinetics of AMPA receptors and the absence of NMDA component in these subthreshold synaptic responses. By combining paired recordings with extracellular stimulations (n = 11), we demonstrated that EPSPs elicited by two different inputs were summed linearly by FS interneurons at membrane potentials below the action potential threshold. We estimated that, in our in vitro recording conditions, 8 +/- 5 pyramidal cells (n = 18) should be activated simultaneously to make FS interneurons fire an action potential from -72 mV. The low level of temporal summation and the linear summation of excitatory inputs in FS cells favor the role of coincidence detectors of these interneurons in neocortical circuits.     

Variance analysis of excitatory postsynaptic potentials in cat spinal motoneurons during posttetanic potentiation

1. Fluctuations in the peak amplitudes of composite excitatory postsynaptic potentials (EPSPs) in cat spinal motoneurons were analyzed during posttetanic potentiation (PTP). Each of a series of identical tetanic stimulus trains delivered to a muscle nerve was followed by 45 test stimuli applied at 2-s intervals. The mean peak amplitude and mean peak variance were calculated for EPSPs evoked by all those stimuli following a tetanus with the same time interval. It was assumed that the variance arises primarily from the probabilistic all-or-none behavior of single synaptic boutons and background noise due to spontaneous synaptic activity and thermal noise in the recording system. The variance was corrected for the contribution from additive Gaussian background noise. 2. If it is assumed that individual synaptic boutons behave independently, corrected mean peak variance and mean peak amplitude are related by a parabolic function. The expected parabolic relationship was seen in 9 of 31 cases studied, and the parameters of the best parabolic fit to the data allowed estimation of some synaptic properties. From these parameters, the mean amplitude of the unit EPSP (v) was estimated to be 102.1 +/- 57.4 (SD) microV. An average of 3.7 boutons comprised each Ia-motoneuron contact system. 3. On average, only 27% of all synaptic boutons given off by the stimulated Ia fibers to one motoneuron were active and releasing transmitter during unpotentiated reflex transmission. The remaining 73% of the synapse population was intermittently silent. The population of boutons which took part in synaptic transmission could be divided into two subpopulations, one with a release probability P = 1 and a second with a mean release probability P = 0.13 +/- 0.086. 4. We conclude that synaptic boutons connecting Ia afferents to motoneurons exist in two populations, one having a high and one a low probability of transmitter release. Transmitter release is quantal, resulting in a unit EPSP of approximately 100 microV measured at the motoneuron soma.     

Probabilistic determination of synaptic strength

This work was carried on to analyze the presynaptic components of synaptic efficacy, which is designated by the term of synaptic strength. To assess the relations between synaptic strength and innervation density, the properties of unitary Cl(-)-dependent inhibitory postsynaptic potentials (IPSPs) evoked in the potentials (IPSPs) evoked in the goldfish Mauthner (M-) cell by single impulses in individual presynaptic cells, including quantal release parameters, were compared with the histological features of the same neurons, determined from their reconstructions after intracellular injection with horseradish peroxidase (HRP). Because the M-cell is a stereotyped target neuron, comparison of the synaptic strength from different experiments was accomplished by using as a quantitative measure of this parameter the mean unitary IPSP amplitude normalized with respect to the reversal potential for Cl- (i.e., the driving force). In 108 experiments at low stimulus frequency, the majority of the normalized responses (63%) were grouped in a rather narrow range, varying about fourfold, or from 1.5 to 6% of the driving force, with results from stained (n = 46) and unstained (n = 62) cells being the same. In contrast, for the same restricted set of responses, the number of presynaptic terminals (histological n) encompassed a larger range, varying from 3 to 52. Impulses in neurons with quite different complements of terminal boutons could evoke similarly sized, normalized IPSPs, and these two parameters were poorly correlated, with there being, at most, a tendency for the responses to increase with histological n for small values of the latter. Quantal fluctuations in IPSP amplitudes were analyzed according to a binomial model having three parameters, p, which is the probability of release, n, which is the number of releasing units and was previously shown to equal the number of presynaptic boutons or active sites, and q, or the quantal size. The normalized quantal size varied randomly, with a mean value of 0.51% (SD = 0.20) and was relatively independent of n. In contrast, the distribution of p, which ranged from 0.17 to 0.74 (mean = 0.40, SD = 0.155), was skewed to the right; this parameter tended to decrease as a function of increasing n. The normalized unitary inhibitory conductance (g'IPSP) underlying an IPSP is equal to the product of npg'q, where g'q is the normalized quantal conductance.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differential effects of tetanus toxin on inhibitory and excitatory synaptic transmission in mammalian spinal cord neurons in culture: a presynaptic locus of action for tetanus toxin

Tetanus toxin reduces monosynaptic inhibitory and excitatory synaptic transmission in mouse spinal cord neurons in culture. Inhibitory transmission is preferentially reduced by the toxin; however, excitatory transmission is also ultimately reduced and blocked by the concentrations of toxin used in these studies. Recordings from monosynaptically connected cell pairs revealed a marked diminution in amplitude of evoked monosynaptic inhibitory postsynaptic potentials coincident with the onset of convulsant action at a time when evoked monosynaptic EPSPs were relatively unaffected. Increased polysynaptic excitation occurred as a result of diminished inhibition. This supports the reduction of inhibition as an important mechanism in the convulsant action of tetanus toxin. Quantal analysis of the late effects of tetanus toxin on the monosynaptic excitatory postsynaptic potential revealed a reduction in quantal number with no reduction in quantal size, thus demonstrating a presynaptic locus of action for the toxin on spinal neurons.     

Synapsin I injected presynaptically into goldfish mauthner axons reduces quantal synaptic transmission

1. Synapsin I was injected into a vertebrate presynaptic axon to analyze its action on quantal synaptic transmission. Two microelectrodes were used for simultaneous intracellular recording from pairs of identified neurons in the goldfish brain. The postsynaptic electrode was placed in a cranial relay neuron (CRN) within 100 microns of its synapse with the Mauthner neuron. The presynaptic electrode impaled the Mauthner axon (M-axon) 50-200 microns from the first electrode. 2. Spontaneous miniature excitatory postsynaptic potentials (mEPSPs) and evoked postsynaptic potentials (EPSPs) were recorded at steady states before and after synapsin I was microinjected into the presynaptic M-axon. Responses were digitized and subsequently analyzed by computer for quantal parameters. 3. In 12 experiments, injection of synapsin I resulted in a reduction in transmission. The decrease in EPSP amplitude began approximately 30 s after the injection, reached a plateau within 10 min, and appeared to be reversible and dose dependent. 4. Injection of synapsin I decreased quantal content (m), with no effect on postsynaptic receptor sensitivity or on amount of transmitter per quantum. Further analysis based on the simplest binomial model for quantal release revealed that synapsin I consistently reduced the number of quantal units available for release (n) although the probability of release (p) was either unchanged or slightly increased. Injected synapsin I may thus bind to presynaptic vesicles and prevent transmitter quanta from entering a pool subject to evoked release.     

Postsynaptic receptor occupancy during evoked transmission at striatal GABAergic synapses in vitro

The effect of benzodiazepines (BZs) on GABA(A)-ergic synaptic responses depends on the control receptor occupancy: the BZ-induced enhancement of receptor affinity can lead to greater peak amplitudes of quantal responses only when, under normal conditions, receptors are not fully saturated at peak. Based on this fact, receptor occupancy at the peak of spontaneous miniature inhibitory postsynaptic currents (mIPSCs) has been assessed in various mammalian neuronal preparations. To use the same principle with compound (or multiquantal), action potential-evoked IPSCs, complications introduced by quantal asynchrony in conjunction with the BZ-induced increase in the decay time of the quantal responses have to be overcome. We used a simple analytic convolution model to calculate expected changes in the rise time and amplitude of postsynaptic currents when the decay time constant, but not the peak amplitude, of the underlying quantal responses is increased, this being the expected BZ effect at saturated synapses. Predictions obtained were compared with the effect of the BZ flunitrazepam on IPSCs recorded in paired pre- and postsynaptic whole cell voltage-clamp experiments on striatal neurons in cell culture. In 22 pairs, flunitrazepam (500 nM) reliably prolonged the decay of IPSCs (49 +/- 19%, mean +/- SE) and in 18 of 22 cases produced an enhancement in their peak amplitude that varied markedly between 3 and 77% of control (26.0 +/- 5.3%). The corresponding change in rise time, however (+0.38 +/- 0.11 ms, range -0.8 to +1.3 ms) was far smaller than calculated for the observed changes in peak amplitude assuming fixed quantal size. Because therefore an increase in quantal size is required to explain our findings, postsynaptic GABA(A) receptors were most likely not saturated during impulse-evoked transmission at these unitary connections. The peak amplitudes of miniature IPSCs in these neurons were also increased by flunitrazepam (500 nM, +26.8 +/- 6.6%), and their decay time constant was increased by 26.3 +/- 7.3%. Using these values in our model led to a slight overestimate of the change in compound IPSC amplitude (+28 to +30%).     

Histaminergic modulation of excitatory synaptic transmission in the rat basolateral amygdala

The effects of histamine on excitatory synaptic transmission between the external capsule and basolateral amygdala (BLA) were examined using intracellular and field potential recordings in rat amygdala slices. Bath application of histamine (20 microM) suppressed intracellular excitatory postsynaptic potentials (EPSPs; 70.3+/-5.1% of control amplitude) in 43 of 64 BLA neurons, and potentiated EPSPs (341+/-81% of control amplitude) in 21 neurons, without changing resting membrane potential or input resistance. The histamine-induced suppression of EPSPs was accompanied by an increase in paired-pulse facilitation of the slopes of EPSPs, suggesting a presynaptic locus of the action. The suppressive effect could be blocked by the selective H3 antagonist thioperamide, and mimicked by the selective H3 agonist R-alpha-methylhistamine, indicating that the suppressive effect is mediated by the presynaptic H3 receptor. The potentiating effect of histamine on EPSPs was not accompanied by the change of paired-pulse facilitation and was not affected by the presence of H1, H2 or H3 receptor antagonists. In addition, the effective concentration of agonist to produce 50% of maximal response (EC50) of the potentiating action of histamine is 49 nM, much lower than the EC50 (470 nM) of the H3 receptor-mediated suppressive effect characterized here. These observations suggest a novel, high affinity and postsynaptically mediated effect of histamine. In extracellular recordings, histamine, at low concentration (200 nM), consistently potentiated field potentials. At high concentration (20 microM), histamine suppressed field potentials, but potentiated field potentials when H3 receptors were blocked. Taken together, these results revealed that histamine, via the presynaptic H3 receptor and a currently unknown mechanism, decreases or increases excitatory synaptic transmission in the BLA respectively. This specific histaminergic modulation of neuronal activity in the amygdala may play an important role in amygdala-mediated physiological and pathophysiological processes, such as fear, emotional learning and memory, temporal lobe epilepsy, and affective disorders.     

Nonuniform release probabilities underlie quantal synaptic transmission at a mammalian excitatory central synapse

1. Excitatory postsynaptic potentials (EPSPs) evoked by impulses in single group I muscle afferents were recorded in dorsal spinocerebellar tract (DSCT) neurons in the spinal cords of anesthetized cats. Fluctuations in the amplitude of these single-fiber EPSPs were determined from measurements of EPSP peak amplitude and contaminating noise (800-4600 trials). 2. In a previous study at this connection, we found that these single-fiber EPSPs fluctuated in amplitude between approximately equal, or quantal, increments. However, these quantal fluctuations could not be described by simple binomial statistics (39). In the present study we have applied further analysis procedures to the same single-fiber EPSPs to formulate a more appropriate probabilistic model of transmission at this connection. 3. In the first stage we have demonstrated that each single-fiber EPSP is composed of the sum of a number (3-30) of uniform quantal events, and that there is extremely little variability in the amplitude of the single quantal event. 4. In a further procedure, we have demonstrated that these quantal fluctuations can be described by a compound binomial model in which each underlying quantal event is associated with a particular, but independent, release probability. The results of this analysis indicate that the probability of transmitter release varies considerably between release sites at this connection. (The use of such a compound binomial model reemphasized previous warnings concerning the interpretation of the results of all statistical models of quantal release. Problems regarding the non-unique nature of N, the total population of quantal events, and other such difficulties are discussed.) 5. A model of transmission at this connection is proposed, in which there are a number of "active" release sites, exhibiting generally high release probabilities, and a number of "reserve" release sites, with zero, or close to zero, release probability. The physiological consequences of such a scheme are discussed.     

Unitary conductance changes at teleost Mauthner cell glycinergic synapses: a voltage-clamp and pharmacologic analysis

1. The magnitude and kinetics of inhibitory postsynaptic currents (IPSCs) evoked in the goldfish Mauthner (M-) cell by intracellular stimulation of identified presynaptic interneurons (unitary responses) and by activation of the recurrent collateral network were determined with single-and double electrode voltage-clamp techniques. 2. The peak magnitude of the inhibitory conductance changes were 5610 +/- 4800 nS (mean +/- SD; n = 13) for the collateral response, and 144 +/- 44 nS (n = 7) for the unitary IPSCs. These synaptic conductances, which are due to the opening of Cl- channels, were independent of the degree of Cl- -loading of the M-cell. 3. The peak amplitude of the collateral inhibitory postsynaptic potential (IPSP) was a constant fraction (0.52 +/- 0.06) of the driving force, which was determined from current-voltage plots for both types of IPSCs and ranged from 10 to 37 mV. These findings confirm indirect measurements from previous current-clamp studies and validate the normalization procedure used to previously calculate synaptic conductances from IPSP amplitudes, a method that therefore may be applicable to other central neurons. 4. At the resting membrane potential, the rise time of the unitary IPSCs was 0.34 +/- 0.07 ms (n = 18), whereas their decay was exponential, with a time constant of 5.7 +/- 1.1 ms (n = 16). 5. Iontophoretic and intramuscular applications of the glycine antagonist strychnine reduced or blocked M-cell inhibitory responses, without altering the excitability of the presynaptic neurons, or the driving force. 6. Amplitude fluctuations of unitary IPSPs recorded during partial blockade by strychnine were analyzed according to a binomial model of quantal transmitter release. In one experimental series, comparison of the binomial parameters before and after applying the antagonist indicated that only quantal size, q, was reduced, whereas n, the number of available release units, and p, the probability of release, were unaffected by strychnine. In a second series, the individual presynaptic cells were injected with horseradish peroxidase (HRP), and it was found that the correlation between n and the number of stained presynaptic boutons and, therefore, of active zones, was maintained in the presence of the drug. No evidence was found for silent synapses in these conditions. 7. The quantal conductance, gq, was estimated from the binomially derived quantal size, in millivolts, and the voltage-clamp measurements of the IPSP driving force and M-cell input conductance. gq averaged 21.5 nS in control conditions and 12.3 nS in the presence of strychnine.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mouse spinal cord in cell culture. II. Synaptic activity and circuit behavior.

1. Neurons in cell cultures of fetal mouse spinal cord (SC) and dorsal root ganglia (DRG) develop extensive synaptic interconnections. 2. No spontaneous synaptic activity was detectable in the presence of tetrodotoxin or an elevated magnsium ion concentration, but statistical analysis of evoked excitatory postsynaptic potentials (EPSPs) indicates that the quantal size was 200-250 muV, which was below the noise level of the recording system used. 3. In a sample of eight RDG-SC and seven SC-SC cell pairs linked by EPSPs, the quantal content of the SC-SC EPSPs was about 3.5-fold larger than for the DRG-SC EPSPs. 4. The extrapolated equilibrium potential for the SC-SC EPSP was about 20 mV positive. The IPSP reversed at a membrane potential of 60-80 mV negative. 5. Some examples of the types of synaptic circuits commonly encountered are given. Only one case of electrical coupling between neurons was found.     

Inhibitory interactions between spiny projection neurons in the rat striatum

The spiny projection neurons are by far the most numerous type of striatal neuron. In addition to being the principal projection neurons of the striatum, the spiny projection neurons also have an extensive network of local axon collaterals by which they make synaptic connections with other striatal projection neurons. However, up to now there has been no direct physiological evidence for functional inhibitory interactions between spiny projection neurons. Here we present new evidence that striatal projection neurons are interconnected by functional inhibitory synapses. To examine the physiological properties of unitary inhibitory postsynaptic potentials (IPSPs), dual intracellular recordings were made from pairs of spiny projection neurons in brain slices of adult rat striatum. Synaptic interactions were found in 9 of 45 pairs of neurons using averages of 200 traces that were triggered by a single presynaptic action potential. In all cases, synaptic interactions were unidirectional, and no bidirectional interactions were detected. Unitary IPSPs evoked by a single presynaptic action potential had a peak amplitude ranging from 157 to 319 microV in different connections (mean: 277 +/- 46 microV, n = 9). The percentage of failures of single action potentials to evoke a unitary IPSP was estimated and ranged from 9 to 63% (mean: 38 +/- 14%, n = 9). Unitary IPSPs were reversibly blocked by bicuculline (n = 4) and had a reversal potential of -62.4 +/- 0.7 mV (n = 5), consistent with GABA-mediated inhibition. The findings of the present study correlate very well with anatomical evidence for local synaptic connectivity between spiny projection neurons and suggest that lateral inhibition plays a significant role in the information processing operations of the striatum.